JP2003087866A - Mobile communication controller, cpu resource assignment method and cpu resource assignment program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a CPU resource assignment method that can variably assign available resources to a CPU of a mobile communication controller. SOLUTION: When there are communication controls A, B, C whose CPU resource usage rate exceeds a limiting point, an individual restriction controller 4 restricts the CPU resource usage rate of the communication controls A, B, C below the limiting point, an overall restriction controller 5 restricts the total CPU resource usage rate of the communication controls A, B, C, and a restriction sharing device 6 decides the share of the CPU resource usage rate of each of the communication controls A, B, C so that the CPU resource usage rate of the entire communication controls A, B, C is the total CPU resource usage rate specified by the individual restriction controller 4 or below.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a mobile communication control device, a CPU resource allocation method, and a CPU resource allocation program, and is particularly suitable for application to variable allocation of CPU usable resources.

[0002]

2. Description of the Related Art In a conventional mobile communication control device, there has been a method of fixedly allocating usable resources of a CPU in communication control. FIG. 6 is a block diagram showing a schematic configuration of a conventional mobile communication control device. In FIG. 6, the mobile communication control device 11 includes a communication control (communication control signal) A,
B, C, a signal receiving device 2, a CPU (central processing unit) 3, and a fixed regulation control device 12 are provided.

Here, the signal receiving device 2 receives the signal transmitted to the mobile communication control device 11. Communication control A,
B and C perform communication control of signals received by the signal receiving device 2 for each protocol. Fixed regulation control device 12
Assigns resources of the CPU 3 that can be used by the respective communication controls A, B, and C in a fixed manner. Hereinafter, regarding the operation of the mobile communication control device 11 of FIG. 6, the resources of the CPU 3 that can be used by each communication control A, B, and C are 20% and 30%, respectively.
% And 20% will be described as an example.

In the mobile communication control device 11, when the signal is received by the signal receiving device 2, the received signal is distributed to the communication controls A, B and C for each protocol. When the signals are distributed from the signal receiving device 2, the communication controls A, B, and C confirm with the fixed regulation control device 12 whether the CPU 3 can be used. In the fixed regulation control device 12,
The resources of the CPU 3 are managed and communication control A, B,
When the use confirmation of the CPU3 is received from C, the communication control A,
It is determined whether B and C can use the CPU 3. Then, in the fixed regulation control device 12, the communication controls A, B, and C are C.
When it is determined that PU3 can be used, each communication control A, B,
The resources of CPU3 that can be used by C are 20
%, 30%, 20% are fixedly allocated, and each communication control A, B, C is notified of the availability of the CPU 3.

When the communication controls A, B, and C receive the availability notification of the CPU 3 from the fixed regulation control device 12, the CPUs
3 and uses the resources of the CPU 3 by 20%, 30%, and 20%, respectively.

[0006]

However, in the conventional mobile communication control device 11, the resources of the CPU 3 are fixedly allocated to the respective communication controls A, B and C, so that CP
Even when the resource of U3 is available, the communication controls A, B, and C cannot obtain the required signal processing speed,
There is a problem that the processing capabilities of the communication controls A, B, and C are reduced.

Therefore, an object of the present invention is to provide a mobile communication control device, a CPU resource allocating method and a CPU resource allocating program capable of variably allocating usable resources of a CPU.

[0008]

In order to solve the above-mentioned problems, according to the mobile communication control device of claim 1, the central processing unit and the resources of the central processing unit that can use communication control are varied. And resource allocating means for allocating each resource. As a result, each communication control
It is possible to obtain a required signal processing speed according to the usage status of the central processing unit, and it is possible to improve the communication control processing capacity.

According to another aspect of the mobile communication control device of the present invention, the communication control is provided for each protocol. As a result, communication control can be performed independently for each protocol, and the efficiency of communication control can be improved. According to another aspect of the mobile communication control device of the present invention, the resource allocating means includes an individual regulation control means for regulating the CPU resource usage rate of each communication control and a total amount of the CPU resource usage rate of the entire communication control. It is characterized by comprising a total regulation control means for regulating and a regulation distribution means for regulating the distribution of the CPU resource usage rate of each communication control when the CPU resource usage rate is regulated by the comprehensive regulation control means.

This makes it possible to variably allocate the resources of the central processing unit to each communication control while preventing the central processing unit from being occupied only by the communication control and delaying the processing other than the communication control. According to another aspect of the mobile communication control device of the present invention, the individual regulation control means includes limit point setting means for setting a limit point of the CPU resource usage rate of the communication control for each communication control, and the communication control is performed. CP
When the U resource usage rate exceeds the limit point, the CPU resource usage rate of the communication control is regulated to the limit point.

As a result, it is possible to prevent the central processing unit from being exclusively occupied by a specific communication control.
It becomes possible to variably allocate the resources of the central processing unit to each communication control while balancing each communication control. According to the mobile communication control device of claim 5,
The limit point is a point at which a signal processing speed with respect to a CPU resource usage rate reaches a limit.

As a result, it is possible to variably allocate the resources of the central processing unit to each communication control while preventing the CPU resources exceeding the processing capacity from being allocated to the communication control. Can be used. According to another aspect of the mobile communication control device of the present invention, the comprehensive regulation control means includes total amount setting means for setting the total amount of CPU resource usage rates of the entire communication control, and the CPU resource usage rate of the entire communication control is When the total amount set by the total amount setting unit is exceeded, the regulation distribution unit sets C of each communication control so that the CPU resource usage rate of the entire communication control becomes equal to or less than the total amount.
It is characterized in that the distribution of the PU resource usage rate is specified.

As a result, the resources of the central processing unit can be variably assigned to each communication control while balancing the communication control and other processing. Also,
According to the CPU resource allocation method of claim 7, the step of variably allocating the CPU resource usage rate of each communication control within the range of each limit point, and the CP of the entire communication control.
Regulating the total amount of U resource usage below a specified value.

This makes it possible to variably allocate CPU resources to each communication control within the range required by each communication control while suppressing the influence on other processing using the central processing unit. Therefore, it becomes possible to improve the efficiency of each communication control while effectively utilizing the CPU resource. According to the CPU resource allocation program of claim 8, the step of variably allocating the CPU resource usage rate of each communication control within the range of each limit point, and the total amount of the CPU resource usage rate of the entire communication control are set. And a step of restricting the value to a specified value or less.

As a result, the CPU resource can be variably assigned to each communication control only by installing the CPU resource allocation program and executing the program, and the efficiency of each communication control can be improved. Become.

[0016]

BEST MODE FOR CARRYING OUT THE INVENTION A mobile communication control apparatus according to an embodiment of the present invention will be described below with reference to the drawings.
FIG. 1 is a block diagram showing a schematic configuration of a mobile communication control device according to an embodiment of the present invention.

In FIG. 1, the mobile communication control device 1 includes:
Communication controls (communication control signals) A, B, C, a signal receiving device 2, a CPU 3, an individual regulation control device 4, an overall regulation control device 5, and a regulation distribution device 6 are provided. Here, the signal receiving device 2 receives the signal transmitted to the mobile communication control device 11. The communication controls A, B, C are the signal receiving device 2
The communication control of the signal received at is performed for each protocol.

When there are communication controls A, B, and C whose CPU resource usage rates exceed the limit points, the individual regulation control device 4 determines the CPU resource usage rates of the communication controls A, B, and C as the communication control. Limit the limits of A, B, and C. The overall regulation control device 5 is a CPU for the entire communication control A, B, and C.
Regulate total resource usage.

The regulation distribution device 6 controls the individual communication controls A, B, C so that the CPU resource usage rate of the entire communication controls A, B, C becomes equal to or less than the total amount defined by the comprehensive regulation control device 4. It defines the distribution of CPU resource usage rates.
FIG. 2 is a diagram showing a method of setting the limit point of the CPU resource usage rate according to the embodiment of the present invention.

As shown in FIG. 2A, the signal processing speed of the communication control A reaches the limit at the CPU resource utilization rate of 40%, and as shown in FIG. At the CPU resource usage rate of 60%, the limit was reached, and
As shown in (c), the signal processing speed of the communication control C is CP.
It is assumed that the limit is reached when the U resource usage rate is 40%. In this case, even if the CPU resource usage rates of the communication controls A, B, and C exceed 40%, 60%, and 40%, respectively, the signal processing speed of each communication control A, B, and C does not increase, and each communication control Even if CPU resource usage rates of 40%, 60%, and 40% or more are assigned to A, B, and C, respectively, the CPU3
Resources are wasted.

Therefore, the CPU of each communication control A, B, C
The resource utilization limit points are 40%, 60%,
By setting it to 40%, the CPU 3 can be used efficiently. FIG. 3 is a diagram showing CPU usable resources of the communication controls A, B, and C according to the embodiment of the present invention.

In FIG. 3, C of each communication control A, B, C
The PU resource usage limit points are 40% and 60, respectively.
%, 40%, CP of communication control A, B, C as a whole
It is assumed that the total U resource usage rate is set to 70%. In this case, the individual regulation control device 4 uses the communication control A
, The CPU resource usage rate of the communication control A is regulated so that the CPU resource usage rate is 40% or less.
For communication control B, the CPU resource usage rate is 60%
The CPU resource usage rate of the communication control B is regulated as follows, and the CPU resource usage rate of the communication control C is regulated so that the CPU resource usage rate of the communication control C is 40% or less. .

On the other hand, the total regulation control device 4 checks the total CPU resource usage rate of the communication controls A, B, and C, and the total CPU resource usage rate of the communication controls A, B, and C is 70% or less. Communication control A, B, C
CPU resource usage rate of Here, the regulation distribution device 6 uses the general regulation control device 4 to perform communication control A, B,
When the CPU resource usage rate of C is specified, the optimum allocation of the CPU resource usage rate of each communication control A, B, C is specified.

As a method of defining the CPU resource usage rate, when the total CPU resource usage rate of the communication controls A, B, and C exceeds 70%, the CPU resource usage of the communication controls A, B, and C is used. The ratio of the usable resources of each communication control A, B, C may be uniformly decreased so that the total rate becomes 70%, or it may be decreased at the ratio of the limit points of each communication control A, B, C. Good.

Further, the usable resources may be preferentially assigned to the specific communication controls A, B and C, and the usable resources of the other communication controls A, B and C may be lowered. FIG. 4 shows a communication control A according to an embodiment of the present invention,
It is a figure which shows the total amount control method of B and C. In FIG.
In the communication control device 1, the CPUs of the entire communication controls A, B, and C
The CPU resource usage rates of the communication controls A, B, and C are variably controlled within a range in which the total resource usage rate does not exceed 70%.

Here, the CPU of the entire communication control A, B, C
Even when the total resource usage rate is within 70%, the individual regulation control device 4 individually checks the CPU resource usage rates of the communication controls A, B, and C. When the CPU resource usage rates of the communication controls A, B, and C exceed 40%, 60%, and 40%, respectively,
The CPU resource usage rates of the communication controls A, B, and C are defined as 40%, 60%, and 40%, respectively.

As a result, each communication control A, B, C has a CP.
Even when the U resources are variably allocated, it is possible to prevent the CPU resources more than necessary from being allocated to the communication controls A, B, and C, and to effectively utilize the CPU 3. Hereinafter, regarding the operation of the mobile communication control device 1 of FIG. 1, the limit points of the CPU resource usage rates of the communication controls A, B, and C are defined as 40%, 60%, and 40%, respectively. An example will be described in which the total CPU resource usage rate of the entire C is defined as 70%.

In the mobile communication control device 1, when the signal is received by the signal receiving device 2, the received signal is distributed to the communication controls A, B and C for each protocol.
When signals are distributed from the signal receiving device 2, the communication controls A, B, and C confirm with the individual regulation control device 4 whether the CPU 3 can be used. In the individual regulation control device 4, the CPU resource usage rate of each communication control A, B, C is managed,
When the use of the CPU 3 is confirmed by the communication controls A, B, and C, the CPU resource usage rates of the communication controls A, B, and C are checked. Then, the individual control device 4 uses the communication control A,
When it is determined that the CPU resource usage rates of B and C are above the limit point, communication controls A, B, and C are above the limit point.
The CPU resource usage rate of the communication control A to the limit point of the communication control A, B, and C.

Further, the total regulation control device 5 checks the total amount of CPU resource usage rates of all the communication controls A, B, C defined by the individual regulation control device 4, and checks the total communication control A, B, C. Total CPU resource usage is 70
If it is less than or equal to%, the individual regulation control device 4 is notified of that fact. When the total CPU resource usage rate of the communication controls A, B, and C is 70% or less, the individual regulation control device 4 controls the CP
Communication control A, B in which U resource usage rate does not exceed the limit point,
C is notified of the availability of the CPU 3 without defining the CPU resource usage rate, and the communication control A, B, and C for the communication control A, B, and C whose CPU resource usage rate exceeds the limit point Notify the limit points of B and C.

On the other hand, in the individual regulation control device 4, the total CPU resource usage rate of the communication controls A, B and C is 70%.
Optimum CP for communication control A, B, C
The U resource allocation is acquired from the regulation distribution device 6. Then, the CPU resource allocation acquired from the regulation distribution device 6 is notified to the communication controls A, B, and C. Communication control A, B,
When C receives the CPU resource availability notification from the individual regulation control device 4, the C accesses the CPU 3 and
The CPU 3 is used for the U resource usage rate.

FIG. 5 is a flow chart showing a CPU resource allocation method of the mobile communication control device 1 according to an embodiment of the present invention. In FIG. 5, when the signal receiving device 2 receives a signal (step S1), the signal is distributed to each communication control A, B, C (step S2). Next, the individual regulation control device 4 checks the CPU resource usage rate of each communication control A, B, C. Then, if there are communication controls A, B, and C whose CPU resource usage rates exceed the limit points (step S3), the CPU resource usage rates of the communication controls A, B, and C are changed to the communication control A, B, and C, respectively. Restrict to the limit point of C (step S4).

Next, the general regulation control device 5 checks whether the total amount of CPU resource usage rates of the entire communication controls A, B, C is less than or equal to a prescribed value (step S5), and the check result is used as the individual regulation control device. Notify 4. When the individual regulation control device 4 receives a notification from the general regulation control device 5 that the total CPU resource usage rate of all communication controls A, B, and C is less than or equal to a specified value, the CPU resource usage rate does not exceed the limit point. The communication control A that notifies the control A, B, C that the CPU 3 is available without specifying the CPU resource use rate of the communication control A, B, C, and the CPU resource use rate exceeds the limit point. , B, C,
The limit points of the communication controls A, B, and C are notified (step S6).

On the other hand, when the individual regulation control device 4 receives a notification from the general regulation control device 5 that the total CPU resource usage rate of the communication controls A, B, and C exceeds the specified value, the communication control A, B , C to obtain the optimum CPU resource allocation from the regulation distribution device 6. Then, the CPU resource distribution acquired from the regulation distribution device 6 is notified to the communication controls A, B, and C (step S7).

Thus, while suppressing the influence on other processes using the CPU 3, the CPU resources are controlled within the range of the CPU resources required by the communication controls A, B, and C to the maximum extent. , C can be variably assigned, and each communication control A, while effectively utilizing the CPU 3,
It is possible to improve the efficiency of B and C. As a result, for example, NMSCP (New Mobile Service)
ce control point) and other packet processing capabilities can be improved.

In the above embodiment, the case where the mobile communication control device 1 is provided with three communication controls A, B and C has been described, but the communication control A, B and C may be other than three. Good.

[0036]

As described above, according to the present invention,
It becomes possible to variably allocate CPU resources to each communication control within a range required by each communication control while suppressing the influence on other processing using the central processing unit.
It is possible to improve the efficiency of each communication control while effectively using the PU resource.

[Brief description of drawings]

FIG. 1 is a block diagram showing a schematic configuration of a mobile communication control device according to an embodiment of the present invention.

FIG. 2 is a diagram showing a method of setting a limit point of a CPU resource usage rate according to an embodiment of the present invention.

FIG. 3 is a diagram illustrating communication controls A, B, and C according to an embodiment of the present invention.
It is a figure which shows the CPU usable resource of.

FIG. 4 is a diagram illustrating communication controls A, B, and C according to an embodiment of the present invention.
It is a figure which shows the total amount regulation method of.

FIG. 5 is a flowchart showing a CPU resource allocation method of the mobile communication control device according to the embodiment of the present invention.

FIG. 6 is a block diagram showing a schematic configuration of a conventional mobile communication control device.

[Explanation of symbols]

1 Mobile communication control device 2 signal receiver 3 CPU 4 Individual regulation control device 5 Comprehensive regulation control device 6 regulatory distribution device A, B, C communication control

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Akira Kaiyama             2-11-1, Nagatacho, Chiyoda-ku, Tokyo Stock             Ceremony company NTT Docomo F term (reference) 5K026 AA19 BB04 CC07 FF02 LL01                 5K034 FF01 FF02 JJ24                 5K067 AA21 HH11 HH21 HH22 KK13

Claims (8)

[Claims] 1. A mobile communication control apparatus comprising: a central processing unit; and resource allocation means for variably allocating resources of the central processing unit that can be used for communication control. 2. The mobile communication control device according to claim 1, wherein the communication control is provided for each protocol. 3. The resource allocation unit, an individual regulation control unit that regulates a CPU resource usage rate of each communication control, a total regulation control unit that regulates a total CPU resource usage rate of the entire communication control, 3. The mobile communication control device according to claim 1, further comprising a regulation distribution unit that regulates distribution of the CPU resource usage rate of each communication control when the CPU resource usage rate is restricted by the restriction control unit. . 4. The individual regulation control means includes a limit point setting means for setting a limit point of the CPU resource usage rate of the communication control for each communication control, and a CPU resource usage rate of the communication control exceeds the limit point. 4. The mobile communication control device according to claim 3, wherein when it exceeds, the CPU resource usage rate of the communication control is restricted to the limit point. 5. The mobile communication control device according to claim 4, wherein the limit point is a point at which a signal processing speed with respect to a CPU resource usage rate reaches a limit. 6. The total regulation control means includes total amount setting means for setting the total amount of CPU resource usage rates of the entire communication control, and the CPU resource usage rate of all communication controls is the total amount set by the total amount setting means. When it exceeds the above, the regulation distribution means regulates the distribution of the CPU resource usage rate of each communication control so that the CPU resource usage rate of the entire communication control becomes equal to or less than the total amount. Three
5. The mobile communication control device according to any one of items 5 to 5. 7. A step of variably assigning a CPU resource usage rate of each communication control within a range of each limit point, and a step of regulating the total amount of CPU resource usage rate of the entire communication control to a specified value or less. CP characterized by
U resource allocation method. 8. A computer comprising: a step of variably assigning a CPU resource usage rate of each communication control within a range of each limit point; and a step of regulating the total amount of CPU resource usage rate of the entire communication control to a specified value or less. A CPU resource allocation program that is executed by a computer.